DE1549852A1 - Arrangement for controlling the recording of alphanumeric characters - Google Patents

Description

; liTI / USTEIELIiE BUIL-GEiERAii ELECiElUG 94, avenue G-ambetta, Paris 2Le / i, France

Arrangement for controlling the recording of alphanumeric characters *

The invention relates to character recording systems, They are generally controlled by a data processing system work, which sequentially coded character representations for the formation of a line of can supply characters to be recorded.

Lieae recording can also take place by punching, but the application of the invention in the present case is specifically intended for a printing machine which, executed in this way, causes the printing of a line of characters by successive printing in which Course, several AeioriGUs of the same type are printed at the same time: j η tier ..

Quick print

109822 / U15

'-4S

8AD

High-speed printing machines generally contain a number of stop members lying in a line, which interact with a continuously rotating type drum. There are known pressure control systems which as a storage arrangement for a character line one character by character in series and for the binary digits of the code groups of the characters in parallel, as well as a comparison arrangement, which in the course of each:

Printing phase the stored character representations with the Oode group of the character type assigned to this printing phase can compare in order to control the actuation of the stop members of the corresponding recording points.

jjie uses a Berien parallel memory a disadvantage, as they are generally a proportionate requires expensive effort. In this regard, it would be very advantageous to have a pure memory array Use serial memory (also called "circular memory") in which the character code groups are on a single channel circulate. However, when the number of characters on one print line is grass, a problem arises because of the length of the circulation cycle peculiar to this type of storage compared to the duration of each of the printing phases. This duration is limited because, on the one hand, it results from the number of types of characters on the drum ura catch and on the other hand results from the speed of the drum.

if

109822 / U15 -—--__, -

, ■ - ■■ - ■ - BATHROOM

On the other hand, if you have a serial memory with a If you want to use reduced cycle time, the connected or assigned circuits will be relatively massive expensive because they work at higher pulse repetition frequencies

. nuts. ..-- ..

A first aim of the invention is the door panel of the. conflicting demands, in particular in that a circulating memory is used as the memory arrangement Used. and still a very satisfactory performance is achieved with a spinning machine, for example should print at least '1000 lines of characters per minute.

Another goal of Irfindung is to create one Recording control arrangement with such an adaptable Operation that a print for one line of characters at triggered any angular position of the lyre drum can be. . ■ -. "'."'.

Another object of the invention is to provide a Print back with facilities that make it possible to that the end of the printing process when printing a line of characters can be determined for the purpose of display at any angular position of the type drum.

An essential and advantageous property of the invention consists in the fact that two marking characters are stored in the Cerienspeicher, which are the characters of an Iiruck-. Divide line-in-two 'files of U character representations. Thanks to diflser i-markings, it is possible for the ■■■ 109822 / UTS io

BAD ORIQlNAL

Serial memory to choose a cycle time that is the same which is or even greater than half the duration of each printing phase.

Accordingly, a recording control arrangement is provided according to the invention, plural marriage cooperates with a recording system which works in successive printing phases, in the course of which several characters of the same type can be printed simultaneously after comparison with a line type code group, a line of printed characters containing 2Ii recording locations, and this arrangement contains a circulating memory which is used for the cyclic circulation of at least 2H + 2 character representations and has an access member at the terminals of which each of the characters is accessible one after the other, each part of Ή characters being preceded by a different marking code group, a comparison arrangement which is derived from the access organ of each circulating character with a character type stored in a register. compares representing code group, two detector arrangements which are designed in such a way that each of them detects one of the marking code groups from the access device, two storage registers controlled by the detector arrangements, of which the first register is used to determine the first marking code group and the second register to identify the other Store tag group, control devices with which the two registers are separated

1Q9S22 / U1S

and operable in any order, two shift registers, each of which consists of at least ΪΤ stages ", the output of each stage being connected to a character recording control element, and switching means under the control of the two storage registers so constructed ,, that after the occurrence of the UmlaufZyklusdes Umlaufspelohers non-synchronous control signal to B _e start of the input of the comparison results supplied by the comparison means, allowing in one or the other verso blows registers, depending on the label code group, said first after receiving the control signal as has been established.

Characterizes the pressure control arrangement according to the invention through additional circuitry designed so that you can erase everyone in the circulating memory Character representation can bring about their identity with the drawing typeneode group has been determined so that the circulating memory gradually increases in the course of the printing process is emptied.

The invention is described below with reference to the drawing described by way of example, therein show *

109 8 22/1415

]? ig.1 the scheme of a memory clock pulse generator, which is assigned to the pressure control arrangement,

Iig.2 a timing diagram relating to the pulse generator,

I ¹ Ig. 3A and 3B the principle of the pressure control arrangement,

Pig, 4 a table to explain a possible arrangement the character code group in the circular memory,

i "ig.5 a logic circuit diagram of an access element of the memory, ]? ig.6 the logic circuit diagrams of the two shift registers, fig.7 the circuit diagram of a stage of the shift registers,

Fig. 8 is the logic diagram of a type code group register and its input control circuits, _v

Iig.9 aie logic circuit diagrams of the two marking code group detectors,

Mg.10 the logic circuit diagrams of the comparison arrangement and the Line deletion control order,

gjg.11

10982a / U15

J ¹ Ig. 11 the logic circuit diagram of a uniform time control circuit,

.. 12 the Logksehaltbild of two arrangements for storage the 3 definition of the marking code groups,

2 ¹ Ig. 13 the logic board of organs which form a pressure connection control arrangement ",

14 shows the logic circuit diagrams of the separate pulse generators and

lig.15 and 16 two timing diagrams to explain the general How the pressure control arrangement works *

The print control arrangement is in a high speed printing machine contain or work with a cutting! printing machine together which, as already mentioned, a number of stop hammers, .that parallel in a line are arranged to a continuously rotating type drum. This machine can be of any currently known suitable Being kind, which is why it is not necessary to describe their mechanical organs which do not form a rope of Erfiu.d-u.ng.

However, it is useful to specify some characteristics more precisely, useful in understanding the results that come with a printing machine in a typical application, 4§i? invention can be achieved. Corresponding to a print line with 160 print

■ ~ * BAD ORDINAL

■ places (characters and spaces) are 160 stop hammers and just as many pressure control elements are provided, each of which in a manner known per se is one of a power amplifier, a transistor generator, etc. can be actuated electromagnet. The type drum rotates at 1000 rpm. Its scope is divided into 64 sectors, each of which has 160 characters of a specific one 'I'ype bears, with the exception of a single sector, the

'bears no sign. Several impulse3: generator orders can be used Deliver impulses in a certain relation to the rotation cycle of the drum, namely one impulse per revolution, defining a reference position of the drum, and one pulse per sector indicating that a series of Printing types will arrive even before the row of stop hammers. The time interval between two pulses this last pulse sequence corresponds to the duration of one printing cycle. This mean duration is therefore im present case 903.8 microseconds. In the description below, these pulses are denoted by D2

• designated. Further arrangements can be another The pulse, which is designated with OS, is only emitted at the beginning of each printing phase when the paper has come to a standstill i.e. when a previous line feed has actually been completed.

There are 62 types of characters provided that can be printed ^ namely the B _u chstaben of the alphabet, .digits and punctuation or different symbols. The coding

1Q9822 / U15

BAD ORiQINAL

the characters ", if stored, requires thus seven binary digits or "bits", namely six binary digits for the binary place values 1, 2, 4, -8,. '1.6 and 32 and a prefix for a parity bit <t or Rather- "imparity bit"). Every oode group of a print draw usually has to be an odd number of digits "1" included. The between-space code group for a space between characters consists of a single digit "1" in the rightmost place.

Before going on to the description of the general principle, a lafcfcimpulsgenerator is examined first, whose I _m pulse are referred to as "memory clock pulses" because they are used to synchronize the operation of the printing control system in close relationship with the circulation cycle of the memory for storing the characters.

It is first on Pig. I and 2 reference genomrae. The generator consists of six bistable multivibrators 11 to 16, which are connected to one another via logic circuits. According to a largely agreed agreement, every such flip-flop circuit is in J ¹ Ig. 1 represented by a rectangle. It is assumed that every flip-flop circuit, which very often consists of two transistors, has two input connections el and eö and two output terminals si and so. In the case of an execution case, in the "0" state of the trigger circuit, a positive voltage of +5 »5 volts is present at the output BÖ , while the voltage at the output st has the value zero ,

/ ins' ■ ", ^

■■. ■; ■■ BADORIÖlNAt

In this state, the flip-flop can only go into the "1" state if its input et is positive Pulse is supplied. Then the voltage of +3.5 [VoIt available at the output si. So that the toggle switch in the State "O" goes back, its input eO must have a positive Received impulse. In the course of the description it is stated that the logical value "1" is replaced by the called positive voltage is shown, while the logical .Zustand "O" is shown by the voltage Full is, at least with regard to an output si.

The connections effected by the various logic circuits in the representation of Pig.i are executed in such a way that the arrangement is approximately: a pulse counter? is similar. It can be seen that 3 is an AND circuit, for example the AND circuit 17, a connection between the output si of a trigger circuit and the Input el causes the following flip-flop. The same applies to the connection between an output sO a flip-flop and the input eO of the following Trigger circuit, with the exception of trigger circuits 12, on the one hand and trigger circuits 14, 15 on the other hand.

Most of the statements, such as the AND circuit 17, have only two inputs and one output. The remaining AND circuits, such as the AND circuit 18, have three inputs. However, each of the AND circuits has at least one input,

109822AUIB "

which "receives certain clock pulses a1, a2, a3 in the manner indicated in lig.1. These pulses shown in the diagram τοη Pig.2 can be supplied by one or more suitable generators, which are not shown as they use any known technology." can correspond. It is sufficient to state that the pulses a1, a2, 3.3 in the present 3 ¹ PlI. have an amplitude of 2 to 3 ToIt, a duration of about 60 IJanoseconds and a repetition frequency of 2.5 MHz, and that their mutual offset corresponds to one third of a bit period which has a duration of 0.4 microseconds.

In addition, a TInd circuit 19 is provided, the inputs of which with the output si of the trigger circuit 12 and with the outputs sO of the trigger circuits 14 and i> are connected. The output of the flip-flop 19 is connected to the input an amplifier 20 is connected. This amplifier, the symbolic representation of which is a sector of a circle, is a Direct amplifier, i.e. a non-inverting amplifier. Such an amplifier is characterized by the fact that it emits a positive impulse at the output, when it receives a positive impulse at the input, due to of the executed connections are provided by the output of the Amplifier 20 has a pulse train B7, the lOlgeiode seven bit periods, i.e. 2.8 MJrkiroseconds, thereby creating a "drawing cycle" in accordance with the Fact is defined that a character representation

the end

109822/1415, - ■ - *

BAD ORlQlNM *

consists of seven bits.

Another U ^ d circuit 21 has four inputs, those with the outputs si of the trigger circuits 13 and 14 and with the outputs SO of the trigger circuits 12 and 16 are connected. The output of the AND circuit 21 controls the input of a direct amplifier 22. Its output supplies the pulse train B4, its subsequent period likewise is equal to a cycle of characters. While a pulse B7 defines the seventh bit period b7, defines an Ifcipulse B4 the fourth bit period b4.

The pulses B71 and BfT are available at the outputs si and sO of the flip-flop 16, while the pulses "B1-6 are available at the output sO of the flip-flop 13. Lie pulses B1-6 extend from the second third of the bit period i> 1 to first third of bit period b3 and from the second third of bit period b5 up to and including the first third of bit period b7.

The aforementioned memory clock pulses become steady released as long as the pressure control arrangement is energized.

Pig.3A and 3B, which join along the line X-X show the basic diagram of the pressure control arrangement. A memory array containing the characters of a pressure cord ^ can store is shown in £ Ortu of a circulation memory 30. This essentially consists of a delay line

109822/1415

SAD QFIiQINAL "^

" ¹³ - 1649852

of any suitable type, in a "preferred embodiment." this delay line works with a torsion magnet ostrict ion, which gives the advantage that they is not very sensitive to temperature changes and has an economic structure.

The element 32 symbolically stands for several organs, namely a logic circuit which receives the clock pulses al, a. "write amplifier and a converter, which in is able to use the Nictield wire of the delay line To impress torsional stress waves. The element 33 also symbolically stands for several organs, such as the output transducer and the sense amplifier, which generates the impulses which represent the character code groups traveling over the delay line. The lungs of the Delay line is dimensioned so that the transit time Between the two converters 162 I pitch cycles of the previously defined type.

The circulating loop also contains an access element 34 as an additional element. This is an offset register of a known type, which consists of seven stages, each stage containing two bistable flip-flops. It can therefore be assumed that the access element 34 consists of two interconnected access element halves KE and RM. The output of the actuator sleeve RB controls the input of the element 32, and the loop is made by the two-wire connection 35 between the

- exit

1Ö9822 / H15 bad

Output of element 33 and the input of the access member half RM completed. The runtime of the access body is equal to a character cycle, which means the total runtime the loop is brought to 163 character cycles, i.e. 456.4 microseconds.

A buffer register 36, which in parallel a character representation can store, which comes from a series-parallel memory of an associated data processing system, is only for Note shown. Seven switches 37, which are controlled by a character input device 38, enable it to enter the character representations corresponding to a print line one after the other in the access organ half RE. For more detailed information on the processes involved in entering characters into the circular memory, please refer to the at the same time Filed patent application ... ("Storage system for storing coded character representations" according to the French patent application 52 548 of March 8, 1966).

It is thus assumed that before the start of each printing operation, the circulating memory 30 is completely filled with character representations is filled, v / which circulate in a cycle that is controlled by the aforementioned clock pulses a1, a2 will. The character representations contain 160 print code groups for the same number of characters to be printed, except for the space code groups, as well as two marker code groups for two marker characters.

109822 / U18 «o

° - ¹⁵ - 1.649852 ^; -

From Pig.4 it can be seen that the character code groups in the circular memory not in the one for the characters in the order provided for in the print line. '.

The numbers 1 to 16 at the top of the columns in the table and the ten labeled "Cycles 1-16.», Cycles 145-163 " Lines show the nesting in a combined porui of the characters. This nesting is due to the fact that the memory of the data processing system, which is in "Allocated times" works, can only deliver one character for several memory cycles. Further be i. '. ie characters are supplied in their printing order. If so assumes that the input operations are uninterrupted the first character (which is preceded by the number 1 in the upper left box) entered during the first character cycle, the second character (2) in the course of the ninth character cycle, the third character in the course of the seventeenth character cycle, etc. Since only 20 characters are entered per cycle of the loop, a little more than eight loop runs for complete pulling of the memory 30 is required if no interruption occurs.

If it is assumed that the table of Pig.4 in spatial Respect is valid, the storage location Pi would correspond to the lower right of the access element 34 of Pig.3A, and that with P163 marked-point top left would be the exit of the Clements 33 correspond. So the character code groups | would be in Pig. 4 zigzag from right to left and bottom to move up.

109822 / UI 5 ^{] 1M} - ^ßA0

- 16- 1649852

The boxes marked with 49 * and 160 * mean the Place a first marking code group KR1 and a second marking code group KR2, these take the ones shown relative positions simply due to the nesting of the character code groups. The essential The condition is that they divide the totality of the character code groups into two equal parts. An empty box in the last line of the table corresponds to a space that is used for shifting the data in the course of the printing phases is necessary, the duration of which is normally eight character cycles.

The very important remark to be made here is that the nesting of the character code groups in the way shown is by no means mandatory. If so, the data processing system uses a different mode of transmission had, there would be no obstacle to having the characters in memory 30 in their normal printing order

κ
were classified. Even in this case there would be a certain leeway for the choice of the position of the marking code groups, since the only condition that has to be complied with is the one previously specified.

From Fig.l the following can be seen: If in etoem given point in time, which is called the reference point in time, the first character (1) is the position P163

leaving.

109822/1415

left, there is the first marker KR1 .in the 67th memory location, the one with 49 '. is designated, and the second marker KR2 is in the 148th memory location, which is labeled 160 ',

V / ie with the majority of similar arrangements a character comparison arrangement 39 (-Fig.3A) is provided. This receives from the outputs of the access organ half BM the character code groups which are currently going through this access organ half. The Y _e rgleichsanOrdnung further receives the Godegruppe the character type that can be printed, the character font changes for each printing phase. A type code group register 40 can receive these character type code groups from an type code group - 'generator 41 when holders 42 are closed', which are controlled by a type code group input device 43. An arrangement 44 for deleting the type code groups is also provided.

The output of the comparison arrangement 39 is via the. Line 45 and logic circuits 46 and 47 with the quantities of two shift registers 48 and. 49 connected, which is used to store the results are determined in the course of each printing phase.

the

owe «« *

The shift registers 48 and 49 consist of the same type Stages, namely the shift register 48 consists of 80 stages and the shift register 49th of 81 stages. Each stage has an input to which shift pulses are applied and an output, as in 50, the is connected to one of the aforementioned pressure control organs. For the moment it should be noted that one of the Outputs of the shift register 49 is not connected to a pressure control element «The shift pulses can from two displacement pulse generators 51 and 52 which under the control of two Storage arrangements 53 and 54 are available. These are used to store the successive determination of the Markers KR1 and KR2. You also control them Lines 55 and 56 the logic circuits 46 and

The outputs of the access organ half BM (Fig.3A) are furthermore connected to two detector arrangements for the determination of the marking characters 57 and 58. These directly control the memory arrangements 53 and 54. * They also control various logic circuits, which are symbolized by the memory switching arrangement which closely cooperates with assemblies 53 and 53.

There

109 822/1415.

As the internal operation there? Print control arrangement and in particular the circulation cycle of the memory 30 is in no way synchronized with the rotation of the type drum of the printer, a drum clock pulse D2 of the type indicated above may appear at any point in time of the circulation cycle. It follows that 'one can not know a priori which l _m pulses D2 will appear first in the access organ half RM of the two fiducial marks KR1 and KR2 after "the arrival of the notional start of a new printing phase characteristic. The assemblies 53, 54 and 59 work together in such a way that the memory arrangements 53 and 54 can only come into operation one single time in succession, namely in the order in which the two markers KR1 and KR2 have been determined, and only after this determination.

An effective pressure phase can go through under the control a unification timing arrangement 60 (1fig.3A) triggered with a pressure lock control arrangement cooperates.

A control connection also leads from the comparison arrangement 39 to a character deletion control arrangement 62. This controls a character deletion arrangement 63. With the aid of these arrangements, as soon as the identity of a print character code group and the type code group issued in the course of the Maer printing phase? found 5wordsn Λ &% + the

BATH".

Character code group at the level of the access organ half RE deleted so that it never circulates in memory 30.

On the basis of the selection functions exercised by the logic circuits 46, 47 of the arrangements 51, 52, 53, 54 can, as soon as the comparison arrangement 39 supplies a signal indicating equality, a binary digit "1" in the leftmost stage or input stage of the shift register 48 or the shift register 49 be entered, depending on whether the memory arrangement or the memory array 54 is active at that moment. Thus, the two shift registers contain 48 and 49 at the end of a Druokphase, but before the release of the Ansohlaghämmer, an arrangement of Digits "1" and "0" formed by the repeated shifts. ] This arrangement is structured in such a way that that when characters are to be printed, digits "1" in certain stages of the registers 48, 49 in the digits which correspond to the positions which are of the character code groups in the circular memory 30 in a previously defined reference time. Of course, the relevant digits "1" are not in the correct ones Places that they are nested as the characters were nested in memory 30. To the To restore the correct position, it is sufficient to connect the output of each stage of the registers 48, 49 to the pressure control element with the appropriate number,

how

109822 / U15 bad original

as will be explained in more detail later.

The existing * but not essential functional parts Connections are in the principle diagram of MgV24 and 3B not all shown so these drawings do not to become uncomfortable, you will be in the following Description discussed in more detail.

lig Form RM. In a manner generally known per se, the outputs of a trigger circuit are connected to the inputs of the following trigger circuit via two AND circuits, for example the AND circuits 66, 67. The AND circuits connected to the inputs of the flip-flops to 657 have an input that receives the clock pulses A1. The AND circuits connected to the inputs of the flip-flops 641 to 647 have an input which receives the clock pulses A2. The mode of operation of this shift register is thus ^: 'i "two-phase". The AND circuits 68, 69 at the input have an input cipher for receiving the output signals all or all of the read amplifier of the delay line. This means that the lines 35 (FIG. 3A) end at these inputs. the

Outputs

109-8227 ΗΊ8

The outputs of the flip-flop 647 are connected to the inputs AED or 1ST of the write amplifier of the delay line tied together.

Parallel access to each circulating character code group is possible at the outputs of the flip-flops 651 to 657 labeled HM1 Ms RM7 and MT to WÜJ.

The character erasing arrangement 63 is formed by diodes 631 to 63, the anodes of which are connected to the inputs eO of the flip-flops 641 to 647. The signal cz has the effect that all flip-flops 64I to 647 are brought into the "O" state, which represents the deletion of the character code group currently circulating J ^l ig.3A correspond and play a role only at the initial entry of the character code groups.

Pig.6 leaves the logical structure of the slash register 48 and 49 more precisely. The shift register 48 entMM; 80 levels ED1 to RD80, which essentially consist of consist of a fast bistable multivibrator. That Shift register 49 contains 81 stages from RD81 to ED161 same kind,

the

109822 / HU ■

■ -. "- 1SA98S2

The outputs s1 of the trigger circuits labeled RD1 to RD161 are with the pressure control organs of the 160 pressure points connected in a special order because it is requiredj the previously explained nesting of the comparison results in the shift registers compensate. A few exemplary details are sufficient for the Understanding what it is about. This is how they control Outputs RD1, RD2, RD3 the 59th, 120th or 19th printing point. The output RD50 controls the 114th pressure point and the Outputs RD79 and RD80 control the 90th and 151st printing point, respectively. Finally, the outputs control the RD81, RB®2, RD160 and RDI61 the 110th, 9th, 40th and 100th printing positions respectively The output of stage RD154 does not control a pressure control element, because this level corresponds to the "space" previously under Reference to Pig.4 has been mentioned.

Fig.? shows the structure of any stage of the shift registers 48 and 49. It is essentially a symmetrical bistable multivibrator to which two input control circuits are assigned. This flip-flop contains two npn transistors T, T ¹ , which are connected in a known manner with diodes and resistors. It should be emphasized that in each branch the two series-connected diodes D1, D2 are silicon diodes which can store a given amount of electricity and which have a threshold voltage of about 0.7 YoIt in the forward direction. The other diodes are germanium diodes for fast switching. The output terminals S1 and SO are connected to the collectors of the transistors I ¹ and T, respectively.

T09822 / U15

An input steaer circuit contains a diode 70 in series with a resistor 71 and a capacitor 0. An assignment of the capacitors C and C is connected to the input terminal ER for the "displacement pulses. The connection point between the diode 70 and the capacitor 3 is to the input Eg The control inputs Og and Od are connected to the terminals S1 · or SO ¹ , which can either be the outputs of the flip-flop circuit of the previous stage of the shift register or the outputs of another control arrangement.

It is assumed that the trigger circuit in the relevant stage ED is in the "0" state, ie that the transistor T is blocked and the transistor T ^{1 is} live. The voltage at output S1 is almost zero, and the voltage at output ίίΟ U is about +3.5 volts. If there is no displacement pulse, the EE terminal is located. to about +3.5 volts. Depending on the control voltages previously received at the inputs Og and Od, only one of the capacitors 0 and C ¹ can be charged at the moment in which a negative displacement pulse is fed to the input ER. Only in the event that the previous stage RD ^{1 is} in the "1" state, the shift pulse is transmitted to the input Ed so that it can then bring the stage RD into the "1" state. The stage RD can only be used if it is initially in the "1" state, ie only in the event that the previous stage RD ^{1 is} in the "0" state, as a result of the shift pulse introduced to it

109822ΠΜ8 ^8A ° ^^ "la.

go to the "O" state. Finally, it is easy to understand that the stage KD "does not change its state when it receives a displacement pulse if stage RD ^{1 is} previously in the same state.

As an exception, the flip-flop circuit of stage RD1 has an input Ei ¹ I, (input for forcing the state “1”), which is connected to connection point 72 via a diode 73. As a result of this measure, a negative polarity pulse fed to input EP1 brings this flip-flop to the "1" state.

The shift registers 43 and 49 are constructed so that they work in so-called "single-phase" operation. From Pig, 6 it can be seen that the inputs of the stages RD1 and RH81, each connected to the inputs Og and Od of Pig. 7 correspond to receive the control voltages mc and mc, which originate from the comparison arrangement 39 directly. If this emits a signal indicating the equality, a digit "1" can be placed in the stage RH1 or in the stage BD81 be entered depending on whether the the shift by one i'tufe causing clock pulses to the input terminals ER1 or the input terminal η ER2. If against it If the comparison arrangement supplies a signal indicating the inequality, the shift pulses only have the Effect that the digits ""! "Already stored in one or the other shift register are changed each time

one

109822/1415 "bath

- Pfi -

be advanced one step. Thus, due to the otherwise very economical structure of these shift registers the logic circuits 46 and 47 and the connections 55 and 56 (Pig, 3B) are omitted.

From Pig. 6 it can be seen that the output RDIbT with a Register MP is connected, which consists of a bistable trigger circuit. It should be noted that this toggle switch is brought to the state "1" at the end of the character input, and that it is during the entire printing process remains in this state, indicating that the circular memory is full of character code groups has been filled.

Pig.8 shows details of the arrangements 40 to 43. Das Type code group register 40 consists of seven bistable ones Flip-flops, each of which has two inputs and two outputs. In the course of each of the successive Printing phases is a different character type neodegrg.ppe an at the outputs! EßüTibis R0T7 and at the outputs RG T1 to ROT7 available. The switches 42 are actually through seven AND circuits 421 to 427 are formed. The order a for entering the type code groups contains an AND circuit and a direct amplifier 75. Two inputs of the AND circuit 74 continuously receive the clock pulses a3 and the memory clock pulses b4. The other input receives the Fignal bc2 * αη

one

109822/1415 *

an output terminal BC2, which can be seen in the circuit diagram of the unification timing arrangement of FIG is. If the signal bc2 is positive, a new Character type code group are transferred to the register 40 from the type code group generator.

The type nc odegruppenlö seilanordnung 44 has seven AND circuits 441 to 447 and a direct amplifier 76. If the signal at is positive, a clock pulse a2, each of one input of the AND circuits 441 to is fed in parallel, the resetting of the register to zero.

Pig.9 shows ". The detector arrangements 57 and 58 for the Identification of the marking code groups. They have the same structure. For example, the detector arrangement contains 57 an AND circuit 771 with seven inputs and two Y amplifiers 781, 791, these arrangements all are connected in cascade. The symbolic representation of the amplifiers 781 and 791 corresponds to a reversing amplifier, an amplifier that outputs the voltage Hull when its input has a positive voltage of e.g. receives +3.5 volts, and vice versa.

The information given next to the inputs of the AND circuits 771 and 772 show how these inputs are connected to the outputs RM1 to RM7 and MT to RM7, which can be seen in Iig.5. Since the 63 code combinations are used for the printed characters, two additional code groups with an even number of digits ⁿ V had to be used

BATH ORIGINAL

can be selected for the markings KR1 and KLl 2, namely 0001111 for KlH and 1111000 for KR2. So long for example the code combination for iJi1 not determined, , is present, there is a positive voltage at the one with IQi 1 designated output of the inverting amplifier 781 is available. Er8t appears when this combination has been determined a positive voltage at the output labeled KR1 of the inverting amplifier 791.

jj'ig.iü shows the structure of the comparison arrangement 33 with its storage register and the character erasure control arrangement 62. The comparison arrangement 39 consists of seven groups of logical f.c 'positions. Each group contains two AND circuits 80, 81 with two inputs, an OR circuit 82 with two inputs and an inverting amplifier 83. The outputs of the seven amplifiers are connected in parallel to a common output terminal 84. Each group of logic circuits corresponds to a binirsbelle. For example, one input of the AND circuit 8) is connected to the output RM1 (on the access organ half RM, I'ig.5) and the other input is connected to the output KOi ¹ I (on the register 4J, FIG. 8). One input of the AND circuit 81 is connected to the output RM1 and the other to the output Lingang JlOi ¹ I connected. It follows from this: As long as there is an inequality between a pressure code group and the character type eCOdegruppe, the AND circuits of at least one group of logic circuits are open, creating a positive voltage

1 0 9 8 2 2 / U 1 5

is applied to the input of the corresponding inverting amplifier, so that a voltage XTuI1 appears at output 84. If, on the other hand, there is equality of the Godegruppen compared with one another, all AND circuits must be blocked be, ao that a positive voltage appears at output 84.

A match memory register contains a flip-flop 85, ■ leren input el with output 84 via an AND attitude connected is. The outputs of the flip-flop 85 are labeled i-0 and HO, respectively. An input of the AND circuit 86 symbolically stands for one or two i-inputs, the one Memory clock pulse and a clock pulse received. In the present Pail is it a pulse b? and one Pulse a2, which means that the AND circuit 86 only occurs in the course of a seventh bit period b? of a drawing cycle and can be open at the beginning of the second third of this period (a2). The shortcut is a nocturnal : olc-hor point in time denoted by b? .a2. Another entrance receives the signal bc4 from the output BÖ4, which is in Mg.12 is recognizable. Thus, the flip-flop 85 can go to the "1" state at the specified point in time when the signal bc4 is positive and an equality is established through the comparison has been. Due to the AND circuit 87, the flip-flop circuit 85 becomes systematic at the next point in time b4.a3 returned to the "O" state.

the

BATH

1 O 9 8 2 2 / U 1 5

" ⁵⁰ " 1b49852

The character erasure control arrangement 62 contains a plurality of AND circuits, each of which is assigned a D; j.rek; fc amplifier. The outputs of these direct amplifiers are connected to a common output terminal IZ . For example, the AND circuit 89 has an input which receives clock pulses and storage clock pulses at a point in time b7.a3. Another input receives the aforementioned signal bc4. So if at such a point in time the flip-flop is in the "1" state, a positive pulse amplified by the direct amplifier 90 is transmitted from the terminal PZ to the diodes 631 to 637 of Pig.5 ", which deletes the character code group currently passing through the access element half RE The function of the remaining AND circuits and 91 to 93 U will be explained later.

The unification timing arrangement 60 is intended to be subordinate to Will be explained with reference to Fig.11. This arrangement consists essentially of three flip-flops 94, 95, 96, which interact with a binary counter that consists of three Levels 97, 98, 99 exist. It should be emphasized that each of these stages has the same structure as jaäe of the stages the shift register 48 and 49 must have the structure shown in FIG. The existing interconnections and the arrangement of the AND circuits 100 to 109 are made such that the arrangement 60 triggers a Druokphase made possible only after at least four character cycles, which are based on the receipt of the drum clock pulses D2 and CS follow the two

Entrances 109822 / U15

Inputs of the AND circuit TOo are supplied. These Delay of four character cycles is determined by the operating conditions of the attack mechanisms.

It should be emphasized that the and circuits 103 and 107 Receive memory clock pulses and hook pulses in such a way that that they can only be used at times b4.a2 bezva. b1 .a2 open ■ are while the AND circuit; 104 in any bit period with the exception of the period b1 at a point in time al can be opened. Furthermore, the and circuits 100 and 101 receive the control signals from the terminals PIN and FIN shown in Fig. 13. The and attitude. 103 can receive a control signal from the KIetame ^ Z that can also be seen in Fig. 13. The AND circuits 108 and 109 can receive a control signal from the ones shown in FIG recognizable terminals VGI 1 and VG2 received.

The circuit group shown in Fig.12 is the arrangements 53, 54 and 59 of 1''Ig.3B equivalent. In particular, the toggle switch 111 has the task of storing the determination of the od group iUH, and the flip-flop 112 has the task of to save the determination of the code group KR2. An entrance each of the AND circuits 113 to 120 is connected to one of the Terminals KK1 or KR2 of the marker detectors shown in Fig. 9 tied together. Furthermore, the AND circuits 114 » 117 and 119 each have an input that is connected to terminal B03

is, and the AND circuit 120 has an input with the

Terminal 109822 / UI 5 BAD ORJGJNAL

- 1049852

Terminal Bö3 is connected; these two clamps are in Fig.11 recognizable. The flip-flop 110 forms an auxiliary register with the associated logic circuits, which makes it possible to that the flip-flop 111 and then the flip-flop 112 in this order or in the reverse order can assume the state "1", depending on whether a marker code group KR1 or a marker code group KR2 was the first to be detected after a drum clock pulse D2. The inverting amplifier "122" is with the output of the AND circuit 121 connected, the inputs of which are connected to the output sO of the flip-flops 111 and 112, respectively. It follows, that a positive voltage is present at the output B04 as long as one of the flip-flops 111 and 112 is in State "1" is.

The pressure closure control arrangement 61 shown in Pig. 13 contains the flip-flops 123 to 126 and the associated logic circuits 127 to 137. The flip-flop 123 has the Task of determining whether a printing process for the printout of a character line has really ended while the toggle switch 124, having previously stored this determination, via registers 125 and 126 the execution of some Can control secondary functions, which put an end point after a printing process, as will be explained later will.

the

109822/1415

The shift pulse generators 51 and 52 are shown in FIG shown. They have the same structure. For example, the generator 51 includes the TJnd circuit 511, the Amplifier 512 and several reverse amplifiers such as the Amplifier 513. The outputs R1 are with the 80 shift inputs ER1 of the shift register 48 (Fig.6) connected. The outputs R2 are with the 81 shift inputs ER2 of the shift register 49 connected. The number of amplifiers 513 and 523 is an inverse puncture of the%: strengthening factor of a single amplifier * These amplifiers provide negative offset pulses every time the AND circuit 511 or the AND circuit 521 is open, i.e. at times b4.a2. The arrangement 51 delivers these pulses when the from the terminal VG1 (Fig. 12) supplied voltage is positive, i.e. between the detection of a marker KR1 and the following detection the marker KR2. In the same way, the ' Arrangement 52 these pulses between the detection of the Mark KR2 and the following statement of the marker KR1,

It must be specified that arrangements not shown either from switching on or while the characters are being entered can be active that they have certain flip-flops in bring predetermined conditions. If under the ehe toggle switch Representing rectangle an input is shown, this means that this flip-flop is initially in the "G" state

brought

109822/1415 _BAD

is brought, which corresponds to the general Pail. if on the other hand, if an input is shown above the rectangle representing a flip-flop, this means that this flip-flop has initially been brought into the "1" state. This is only for flip-flops 97 through 99 of the counter by Pig.11 the Pail.

The operation of the pressure control arrangement will now be examined with reference to Pig.15. As already was mentioned, a first printing phase after the coincidence between a signal OS and a drum clock pulse D2, like the drum clock pulse shown on the top line of the time diagram of Pig.15. That I the flip-flop 124 (Pig.13) is in the »0» state, the signal PIN is positive. Thus, at the next point in time al, the AND position 100 (Pig. 11) brings about the toggle switch 94 in the state "1", and the output B01 becomes positive. At the following point in time a2, the arrangement 44 (Pig. 8) actuated, and the possible content of the type code group register 40 is cleared (compare line ROiE of the timing diagram). In the illustrated timing diagram, it is assumed that the pulse D2 was received at the end of a bit period b5 is. If the D2 pulse arrives earlier, the events noted earlier will occur in the course of the XO character cycle earlier on. Nothing happens on each pail up to the point in time b4.a2 of the next cycle X1. Since at this point the

exit

109822/1415

15 A 9: 85.2

Output T0 of Xippsclialtung 123 (Pig. 13) is positive, brings the and ^ circuit 103 (Fig. 11) the flip-flop 95 in eng state "1", and the output BÖ2 becomes positive. At the following point in time b4.a3, the arrangements 42 and 43 operated to input the first Effect character type code group in register 40. in the The provision is also made at the following point in time b5.a1 the flip-flop 94 in the state "0", which is of the r-attitude 102 is evoked.

The operation of the counter of Fig. 11 begins at the end of this Cycle X1 in the Etriode b7. At time b7.a3, the and circuit 106 sets the flip-flop 97 to the "0" state. The output si of this flip-flop provides a negative one pulse which brings the flip-flop 98 to the "0" state. At time b1.a1 of cycle X2, the TJ.nd circuit 105 switches flip-flop 97 to the "1" state. At the point in time b7.a3 of this cycle, the AND attitude brings 106 the flip-flop 97 in the state "0". The output si of this flip-flop provides a negative pulse, which the flip-flop 98 brings it to the "1" state. The exit So this flip-flop provides a negative pulse which brings the flip-flop 99 into the "0" state. B $ ai iei.tdiagratnm clearly shows the Zuätanasänderjingen of :. Flip-flops 97, 98, 99 in the course of the following cycles, X3 and X4. It can be seen that at the point in time bl, "a1 dee

. cycle

Cycle X5 the three flip-flops have all returned to the "1" state, thereby expressing the fact that four character cycles (X1 Ms X4) have been counted. At the following point in time b1.a2, the AND circuit 107 is opened, as a result of which the flip-flop circuit 96 is brought into the "1" state. The output BC3 becomes positive. It follows that next time b1.a3 the AND circuit 104, the flip-flop 95 in the Z _u "O" stand resets.

At the following point in time b4.a3, the AND circuit 129 (Pig.13) brings the flip-flop 123 to the "1" state, so that its output si becomes positive and its output sO (PZ) becomes negative. The output PZ supplies a reverse voltage, since this prevents the flip-flop 95 from going into the "1" state when fed to an input of the AND circuit 103 (FIG. 11). Then nothing more takes place until the end of cycle X5, and also during a variable number of character cycles, which are symbolically represented in FIG von i ^I ig.9r This statement marks the beginning of a withdrawal phase e.

At the beginning it is assumed that the marker KR1 first goes through the access organ half RM. The output KR1 (Fig. 9) then supplies a positive pulse in the period b7 of a cycle XA. It follows that in the following time purict b7.a3

BAD OfWiNAL

1 0 9 8 2 2/1 U 5

the AND circuits 114 and 119 (FIG. 12) are open and bring the flip-flops 111 and 110 into the "1" state. Since the output T01 becomes positive, the AND circuit 108 ' ^{resets the flip-flop 96 to the state "O 11} at time b1.al of the next cycle XE. The flip-flop 111, which stores the detection of the marker KR1, remains during at least 81 character cycles, ie until the marking character KR2 is detected in the state "1". If this detection occurs, the AND circuit causes the flip-flop circuit 112 to change to the state "1" at a point in time b7.a2. that the AND circuit 115 causes the resetting of the flip-flop 111 to the state "0" at the following point in time b7.a3. The flip-flop 112 stores the detection of the flag KR2 for at least 81 cycles, ie until a new detection of the flag KR1. If this determination occurs, the AND circuit 118 is opened at the time b7.a3 '., So that the flip-flop is reset to the "0" state At point ■ the AND circuit 120 causes the flip-flop 110 to be reset to the "0" state.

v / hen to B _e beginning it is assumed that the flag KJ ± 2 first appears, brings dann'die AND circuit 117, the flip-flop 112 at the time b7.a3 in the state "1". Later, when the flag KR1 is detected, the AND circuit 113 effects the transition of the toggle circuit

BATH

109822/1415

to the state "1" at time b7.a2 at the end of the cycle. At the following point in time b7.a3, the AND circuit 118 brings the flip-flop 112 back to the state ¹¹ O ". Even later, when the flag KH2 is detected again, the AND circuit 115 brings the flip-flop 111 back to the" 0 "state. Es It should be noted that this time the AND circuit 110 has remained permanently in the state "0." It should also be remembered that the output voltage BC4 is in the time interval between the first and the second detection of the same marking character, ie during the duration of a withdrawal phase Fig. 16 shows how the withdrawal phases fit into the pressure phases delimited by the successive pulses D2 the shifts can be shown, which when the marking characters KR.1, £ R2 are determined in relation to the Imp ulse D2 can enter. Otherwise, the duration of an ingestion phase is nothing other than the circulation time of the circulating memory 30.

Let us now return to the first cycle XE of Fig. 15, it is assumed that the first removal phase is initiated by the detection of the marker KR2 has been, and that none of the stored in memory 30

- - ν character code-

109822/1415

Character code groups with -the character type code group stored in register 40: is identical. Since the voltage ve2 is positive, at time b7.a2 the ünd circuit ■ 5,21 of the arrangement 52 (S ¹ Ig. 14) transmits a positive pulse to the direct _{amplifier 522 5} so that the inverting amplifier 523 sends a shift clock pulse to the inputs ER2 of the shift register 49 deliver. This impulse has no great effect because in principle all stages of registers 48 and 49 are in the "0" state.

It is clear that at the following point in time b7.a2 the AND circuit 86 (FIG. 10) remains blocked despite the positive voltage b: n4, since the output 84 of the Veiji calibration arrangement is a signal indicating the inequality, that is, a voltage. The AND circuit 85 remains in the "0" state, and the AND circuit 89 remains blocked _3, which prevents the ZeiclienolösungTOr.

There is a detector circuit for the detection of the Blank provided, which is the input sO of the toggle switch 123 of Fig. 15 controls. An input of the AND circuit 130 receives the output of inverting amplifier 128, which in turn to the output of the AND circuit 127 When the memory has 30 circulating character code groups contains at least one bit of these character code groups is a digit "1". At least one of the entrances

the AND circuit 127 receives a voltage NuIl through which the AND circuit is locked so that the output signal

_s of

109822/1415 bath

of inverting amplifier 128 is positive. In the following time b7.a3 all inputs of the AND circuit 130 receive a positive voltage, whereby the flip-flop 123 in the State "0" is returned, which resumes its normal function, which consists in its state "0" indicate the presence of character code groups in memory 30.

In each of the following cycles, a shift pulse is sent to the register 49, which is followed by a comparison, which again supplies an inequality result. This happens during the first H ^"4 JLfte the current lint would take phase. Ka ch the detection of the marking character 1011, that is, during the second half of the Ent would take phase, carried out similar operations, except that now the assembly 51 to the shift pulses to Shift register 48 supplies.

It is now to be investigated what the operation is, for example, in the course of the first half of a withdrawal phase as before, '.but in the case that a character code group is identical to the character type code group belonging to the current printing phase. It is obviously that at the end of the drawing cycle the output of the comparison arrangement 39 (Pig.10) is positive, and that at time b7.a2 the AND circuit 86 brings the flip-flop to the "1" state (see line MC, FIG. 15).

in the

109822 / U15 BAD

At the next point in time b7.a3, since the AND circuit is open, the output terminal I ¹ sends a pulse to the inputs of the access organ half RB (3? Ig.5), to which the diodes up to 637 are connected, which causes the cancellation of the character code group just compared ". In the course of the

■ '- ■■ -.' ■ ι. ■ ■ ■

following cycle, for example cycle XE ¹ (Pig.15).

receiving the inputs of the level of V _e RDSI'beim applying rschiebeimpulses to the inputs of the shift register ER2 49 at the time b4.a2 a positive voltage and a negative voltage (mc and MOE). As previously explained, this causes a digit "1" to be entered at this stage. At the next point in time b4.a3, the AND circuit 87 brings the flip-flop 85 back to the "O" state. In the course of further cycles, the same events are repeated each time a comparison results in equality, and at the end of a withdrawal phase, after repeated shifts, those stages of registers 48 and 49 which contain a digit "1" are able to control the operation of the pressure control organs of the corresponding pressure points.

Let us now consider the case that one through the access organ half Print character code group going RM is the aforementioned space code group. It is on Pig.10 Reference is made to an arrangement not previously described for the detection of this space code group shows. This arrangement includes two AND circuits 24 and 26, and

ν 8AD 0RIOMAL

109 8 22 / U15

- Δ. ¹ ? -

two direct amplifiers 25 and 27. It is necessary to prevent the entry of the digits "1" in the shift controls during the printing phase, during which the code group register supplies the space code group 0000001 and the comparison arrangement can determine the space code groups circulating in the memory 30. With each such determination, the toggle circuit "goes to the state" 1 "at a point in time b7.a2 of a character cycle. Since the six inputs of the AND circuit 24 are connected to the outputs RM1 to RM6 of the access element half RM and one input of the AND Circuit 26 is connected to the output EM7, this arrangement also detects every space code group. Another input of the AND circuit 26 receives the signal Is (for example: manual control), which is always positive during a printing process This AND circuit opens during any withdrawal phase. During a period b7, the output ZB is positive. It follows that in the next time point bl.a3, the AND circuit 83 supplies a pulse to the input sO of the flip-flop circuit, so that it is earlier than at other printing phases is reset to the state "0". In this way no-digit "1" yes - one of the registers 48 and 49 can be entered eichenZ _e itpunk1; The AND circuit 93 causes a positive pulse to go to the output FZ, which results in the deletion of the space code group in the access organ half RE.

It

1 0 9 8 2 2 / U 1 5 ' bath

It is easy to understand that after printing all of that one print line "forming characters in the memory 30 only tiocli the two markers EE1 and KR2 run around.

During the passage of the marker code groups through namely, the access element half RM supplies the comparison arrangement always a result for an inequality, and it is obvious that the marker code groups during

of the effective print phases are never deleted. ·

Let us now consider the final gates immediately after the last effective pressure phase. A new pulse D2 triggers the operation of the uniform timing circuit 60 of I? Ig «11 again. 3? Ie with reference to Iig. The Y processes described in 15 are repeated again in the range of the cycles .K1 to XA _s d "ho until the first detection of a marking character" Let it be accepted? that this is the Martierungszeichen KR1 at the end of the cycle XA.

Since there is no longer any print character code group in memory 30, all inputs of the TJnd circuit then receive 127 (iig.13) a positive voltage »The output voltage of the inverting amplifier 128 is therefore zero. Datbau follows, At time b? .a3 of cycle ZE, let the AND circuit 130 is locked, and the register 123 is not in the state. "0" deferred, causing the apparent emptying of fj memory 30 (with the exception of the marker KR1 and KR2) and the apparent end of printing are displayed. The same takes place in the course of the following XJS cycles.

■■■ -— ■ - * In particular 109822 / U15 bad. original ■

In particular, the AND circuit 130 remains in the determination of the marker KR2 and then at the renewed plague position of the marker KR1 blocked because the ■ from the outputs KR2 or KR1 of the detectors 58 and 57 supplied voltage has the value zero.

It is necessary to wait for a new pulse D2, which again triggers the operation of the unification timing control circuit 60 (Ifig.H). Let it be cycle X1 Ci ¹ Ig. 15) considered when the flip-flop 94 has changed to the "1" state and the output BOT is positive State "1" is. The flip-flop 124 therefore goes to the "1" state in order to control the termination operations. On the other hand, the AND circuit 103 (Pig.11) is blocked a little earlier because the voltage pz is zero. Therefore, the transition of the flip-flop circuit 95 and 96 to the "1" state is prevented. At the next point in time b5.a1, the AND circuit 102 can no longer trigger the resetting of the flip-flop 94 to the “0” state. This is taken over by the AND circuit 101 because it has an input which is connected to the output PIN of the flip-flop circuit 124. Therefore, the activity of the unification lease time tax attitude is stopped here.

1 0 9 8 2 2 / H 1 p

Since the flip-flop 96 has remained in the "O" state, supplies the output BC3 the voltage lull. So are in the moment the determination of the marker KR1 or KR2 the AND circuits 114 »Έ 17 and 119 (Fig. 12) blocked, so that they initiate the storage devices 53 and for preventing the marking characters.

In the character erasure control device 62 (Fig. 10), two so far not mentioned AND circuits are provided. These are the AND folds 91 and 92, each of which has an input which receives the now positive voltage from the output FIN of the flip-flop 124. Thus, when the marker KR1 (or KB.2) is detected, a positive pulse is transmitted to output 5 ¹ Z at a point in time b7.a3. This obviously results in the deletion of the marker KR1 (or KR2) in the access organ half RE.

It can also be seen that an input of each of the AND circuits 134 and 136 (I'ig.13) receives this positive pulse originating from the output EZ. Thus, when the flag KR1 is set, the register goes

125 to the state "1". The same goes for the register

126 at the detection of the marking sign ^^ ER2.

BAD ORiGtNAl,

109822 / 141S

" ⁴⁶ " 1548852

An AND shadow 28 (Fig. 6) is provided, the two Has inputs which are connected to the outputs KU and KD of the flip-flops 125 and 126. If those Both flip-flops are brought to the "1" state, this AND circuit causes the register HP to be reset to the state "0", which indicates that the memory is now completely empty.

Another AND circuit 29 (Fig.6) is with the input for forcing the state "1" of stage RD1 of the storage register 48 connected. It also has two inputs connected to the outputs KU and KD, and they causes a number "1" to be entered in this stage under the above conditions. These last two operations are not essential, but they are useful when making certain controls of the control arrangement during the operation can be used to enter code characters in the circular memory. The transition of the register MP to the "O" state also has the effect of resetting the flip-flops 125 and 126 in the "O" state with the aid of the AND circuits and 137 is triggered at a point in time a3 of a period b1, b2, b5 or b6.

It was found that the marker code groups KR1 and KR2 play an essential role in controlling the Sequence and the chaining of the operating phases of the numerous devices of the pressure control arrangement. So it is Fact that there are two markers, too

109822 / U16

owe the comparison of the characters - '"at each Druok phase arbitrarily with one or the other half the characters! circulating in the serial memory can begin.

This organization is "special in terms of time savings advantageous, because "if there are not many or favorably distributed character types can lead to the complete. The time required to print a line of characters must be significantly less than the duration of one revolution of the type drum.

The invention is of course not restricted to the details of implementation shown and described, for it is obvious. ₉ that structural changes to certain arrangements are within the normal range of specialist knowledge.

Patent test

BATH ORIGINAL

ms

Claims (9)

Claims f AJ Print control arrangement for controlling a printing mechanism with a type drum in connection with a pulse generator arrangement, which generates a sequence of drum position pulses, with a first memory which contains the coded representations corresponding to a line of characters to be printed, a comparison arrangement which in the course of successive printing phases compares these character representations with a line type code group which is different for each printing phase, and with a second memory which is designed so that it controls the stop members of the corresponding printing positions as a function of the comparison results, characterized in that the first memory (30) a pure serial memory and is designed in such a way that at least 2N + 2 character representations circulate in it cyclically, which are divided into two equal parts, each preceded by a different marking character, so that the first memory only has a single access element (54 ) for access to the circulating characters, which enables the comparison arrangement (39) to compare the characters in succession, that two detector arrangements (57 »58) are connected in such a way that they each fix one of the two marking characters from the access member. Btellen can 109822 / U1B sad can that the detector arrangements have two storage registers (53, 54) are associated with the determination of the one "or the other marking character in a ■ any order can save that second Memory two shift registers (48, 4.9) are provided ■ «_ ■■ ■■ ■ .- ■■ - each of which consists of at least IT stages ₉ the outputs of which can control the stop devices, and that reversal arrangements are controlled by the two storage registers in such a way that they allow the beginning of the input of the comparison results in one or the other shift register depending on which of the marking code groups was detected first after a drum position pulse, whereby the circulation time of the first memory can be greater than half the time interval between two successive drum position pulses. 2. Pressure control arrangement according to claim 1, characterized in that that there are additional circuits (62,63) under the control by the comparison arrangement on the access organ (34) ■ ■ # designed as a magnetostrictive delay line first memory (30) act in such a way that the deletion every character representation is caused whose "equality has been identified with the character type code group, so that the first reservoir is gradually emptied. 1543852 3. Print control arrangement according to claim 2, in which the operation of the various arrangements and circuits is synchronized by a clock pulse generator, characterized in that a standardization timing control circuit is provided which contains a logic circuit (10O ¹ ) which receives an adjustment pulse before each printing phase, and several bistable flip-flops (94 to 96) which then control the counting of a predetermined number of character cycles by a pulse counter (97 to 99) and finally allow one of the two storage registers (53, 54) to be excited. 4. Pressure control arrangement according to claim 3, characterized in that that the bistable circuits (111, 112) of the storage registers (53, 54) interact with an additional bistable circuit (110) via logic circuits, which control the mutual connections in such a way that the two storage registers both have a control voltage in the time interval between the detection of the first tag code group and the detection of the second Marking code group as well as in the time interval between the detection of the second marking code group and the Provide identification of the first marking code group. 5. Print control arrangement according to one of the preceding claims, characterized in that the access member (34) consists of one Yersohieberegister consists ", which contains. Efoenso many levels, how 109822/1415. ^Ö * ° ° * 'W how bits are contained in a character code group, that each stage contains two bistable flip-flops, '· and that the transit time through the access organ is equal to ·. a drawing cycle. 6. Print control arrangement according to claim 4, characterized in that each of the Yersah shift registers (48, 49), which work in single-phase operation, has a series of shift inputs, that two groups of ton shift pulse generators (51 »52) are provided which are input with the shifts of the one or the other shift register is connected, and that each group is controlled by the control voltage, which is supplied by one of the associated storage registers (53, 54), in such a way that the first and second shift registers ¹ must separate the shift pulses one after the other as a result of the determination of the first marking code group or the second marking code group received. Pressure control arrangement according to Claim 6, characterized in that the input of the first stage (BDI Tmsw. BD81) of each of the shift registers (48, 49) is controlled by the comparison arrangement (39) in such a way that, if it supplies an equality condition, .-a number ^l! 1 "of that in the first stage 'Yeracliietoeregietare is input, the. Yerschiebeeingänge receive the Yerschiebeimpulse. 8th" iS22 / H1i BAD OFiIQlNAL 9. Print control arrangement according to claim 7, characterized in that a space code group detector arrangement (23) is connected to the access element (34) of the first memory (30) and a register (85) of the comparison arrangement (39) and a character erasure arrangement (93, 90, I ¹ Z) controls in such a way that when a space code group is detected, the introduction of a digit "1 ¹¹ in the input stage of one" or of the other shift register (48, 49) prevented and the deletion of the space code group in the access member (34) is effected. 9. Print control arrangement according to claim 8, characterized in that a print closure control arrangement (61) is provided which contains logic circuits in connection with two bistable flip-flops and can determine the fact that all character code groups in the first memory (30) have been deleted in order to prematurely interrupting the operation of the standardization time control arrangement (60) after the receipt of a drum position pulse and causing the deletion of the two marking code groups in the access element (34) of the first memory. 1 09822 / HI 5